Underwater Light Display Device and System

ABSTRACT

A light display system and device for use in a body of water or other liquid is described. The light display device may be controlled remotely via a control hub and/or control panel, or controlled by internally preprogrammed commands. A plurality of light display devices may be controlled in selected, choreographed sequences to provide various unique visual displays including, for example, geometrical patterns and/or naturalistic patterns giving the impression of organic phenomena such as swarming fireflies, bioluminescent creatures and the like.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No.62/297,786, filed Feb. 19, 2016, the contents of which are incorporatedherein by reference.

FIELD OF THE INVENTION

The present invention generally relates to floating or underwater lightdisplays, including wireless floating or underwater light displaydevices and systems, and a system and method for controlling suchdisplays.

BACKGROUND OF THE INVENTION

Various types of underwater and floating light displays exist.Oftentimes, the light display is located in a reservoir having a floorand walls. In certain existing systems, before the reservoir is filledwith water, a network of underwater light display devices may beembedded in or attached to the bottom or walls of the reservoir. Thesemay include the underwater light display devices themselves, as well assupporting lines such as electrical lines. Alternatively, some existinglight displays float on the surface of the water in a reservoir. Theymay be free floating or tethered to an underwater control portion.

These existing underwater and floating light display devices may providevisual effects, but if they are fixed to the bottom or walls of thewater reservoir, free floating in the reservoir or tethered, there issome limitation on the variety of visual effects they can produce. Forexample, fixed underwater light display devices typically cannot providethe appearance of a chain of lights moving into various geometricalpatterns or a cluster of lights moving in a naturalistic flowing orswarming pattern reminiscent of organic phenomena such as fireflies orbioluminescence.

Accordingly, there is a need for a floating underwater light displaydevice for use in a light display system that includes one or morefloating or underwater light display devices that are wirelesslymaneuverable about a display reservoir to provide unique visualdisplays. There is also a need for a floating or underwater lightdisplay device comprising a light and a multidirectional propulsionsystem. There is also a need for a floating underwater light displaydevice that is capable of being controlled wirelessly.

SUMMARY OF THE INVENTION

In an aspect of the current invention, a floating or underwater lightdisplay system is described that includes one or more light displaydevices that are wirelessly and remotely controlled within a displayreservoir to provide unique visual displays. A plurality of lightdisplay devices may be wirelessly controlled by commands received viaone or more control hub. The control hub may receive commands via acontrol panel. The system may be operated by computer program or mobileapplication, such as an application on a tablet or mobile phone.Alternatively, the system may be manually controlled.

The light display device may be maneuvered in selected, choreographedsequences, which may include varying the location, direction, speed,light color, light brightness and other properties of each of the lightdisplay devices. A plurality of such light display devices may bewirelessly and remotely controlled to provide various visual displays.For example, the display devices may be controlled to form geometricalpatterns and/or naturalistic patterns giving the impression of organicphenomena such as swarming fireflies, bioluminescent creatures and thelike.

In another aspect of the current invention, a floating or underwaterlight display device is described that comprises a light, amulti-directional propulsion system and control electronics. The lightdisplay device is preferably free moving, i.e., not dependent on wires,cables, tracks and the like, and wirelessly controllable. It may alsoinclude one or more rechargeable battery packs. It is capable ofreceiving a data stream including commands and acting on the commands asappropriate, for example, by moving to a new location, adjusting itsspeed, light color, light brightness and other properties.

In another aspect of the current invention, a floating or underwaterlight display device is described that may be wirelessly, remotelycontrolled and/or operated via a control hub. Alternatively, the devicesand system may be controlled from devices such as a phone, tablet orother device.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present invention will now be described, by way ofexample only, with reference to the following drawings.

FIG. 1 is a system view of a floating or underwater light displaysystem.

FIG. 2 is a side view of a floating or underwater light display device.

FIG. 3 is a perspective view of a floating or underwater light displaydevice.

FIG. 4 is an exploded view of a floating or underwater light displaydevice.

FIG. 5 is a bottom view of a floating or underwater light display deviceillustrating the potential for multi-directional movement.

FIGS. 6A-6D are a series of pictures illustrating an example of how thelight display devices may be controlled to form a visual light display.

FIGS. 7A-7I illustrate examples of various visual light displays whichmay be provided by the light display system of the present invention.

FIGS. 8A-8B show examples of various geometric pattern visual lightdisplays which may be provided by the light display system of thepresent invention.

FIGS. 9A-9C show examples of various naturalistic pattern visual lightdisplays which may be provided by the light display system of thepresent invention.

FIG. 10 illustrates an example of a multi-directional path for a lightdisplay device in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The current invention is now described with reference to the figures.Where the same or similar components appear in more than one figure,they are identified by the same or similar reference numeral. Theinvention is described herein with reference to water. However, thesystem of the current invention may be used with other liquids andcombinations thereof, and such uses are within the scope of theinvention.

Light display system 1 of the current invention is illustrated in FIG. 1and may provide various visual light displays within a display pool orreservoir. System 1 may include devices that float at or near thesurface of the water and/or that may be located underwater. As such, thecurrent invention includes both scenarios, and the use of the termunderwater is not meant to be limiting unless expressly stated as such.Light display system 1 may include one or more light display devices orpods 10 which may float and move along or near a surface of water ormove underwater, and which may be remotely controlled by one or morecontrol hub(s) 20. As shown in FIG. 1, a single control hub 20 mayremotely control one or more light display devices 10. For example,control hub 20 may remotely control twenty (20) or some other number oflight display devices 10. In another embodiment, light display system 1may include a plurality of control hubs 20, each of which may remotelycontrol a plurality of light display devices 10.

Display system 1 may also include control panel 30 which may remotelycontrol the plurality of light display devices 10 via the appropriatecontrol hub(s) 20. As shown, the communication between control panel 30,hub(s) 20 and pods or display devices 10 may occur through WiFi or otherappropriate wireless network protocol.

As illustrated in FIG. 1, display system 1, may be operated by computerprogram or mobile application, such as an application on tablet ormobile phone 35 or other device. In this embodiment, a user maycommunicate via his or her device 35 with the control panel 30 and sendcommands to pods 10 though appropriate control hub(s) 20. Alternatively,the user may communicate directly with control hub 20 to send commandsto pods 10.

As noted above, control hub 20 may send out a data stream 40, forexample, over a WiFi network. The data stream may include, for example,device IDs, position commands and other commands to control thedirection, speed or other aspects of devices 10. In a preferredembodiment, light display devices or pods 10 may receive a uniqueposition command, compare it to its current position as determined by aGPS tracking system 50, and then move to its new position asappropriate. All or some number of devices 10 in system 1 may involveGPS tracking.

Other controls may be also communicated via data stream 40. For example,commands concerning timing and/or speed, light color, brightness and/orsaturation may also be provided by data stream 40. It is preferred thatthese commands result in enhanced visual displays.

Display system 1 may provide that each of the underwater light displaydevices 10 independently moves around the display reservoir. Forexample, system 1 may control pods or devices 10 so that they may moveto any location within the display reservoir, even right up to edgesand/or into corners or nooks. By independently controlling the pluralityof light display devices 10, system 1 preferably provides numerouspossibilities for creating unique visual light displays which aregenerally not possible with traditional light systems using fixedlights, or lights that are moveable only along lengths of cable, ortracks in fixed patterns.

Control hub 20 may include a battery charger, for example, an inductivecharger. Pods or devices 10 may dock to or otherwise engage with theappropriate control hub 20 to recharge their batteries, for example, byan inductive charging.

The components of system 1 are preferably located to enhance theappearance of its environment. For example, control panel 30 may belocated in an out of the way place so that it may be relativelyconcealed. However, control panel 30 is still preferably located so asto not disrupt its network connection. Hub(s) 20 may be located in acorner or inconspicuous place in the reservoir. However, where pods 20are configured to be docked and charged by hub(s) 20, it is preferredthat hub(s) are located to allow such docking.

With reference to FIGS. 2-5, an embodiment of light display device 10 isnow more fully described. In a preferred embodiment, light displaydevice 10 comprises pod 100. Pod 100 may have any shape and sizesuitable for moving about a given display reservoir. In general, pod 10may travel underwater or at or near the water's surface. For example, aportion of pod 10 may protrude above the water's surface. Pod 100 mayhave a generally spherical shape, but other shapes may be used. In apreferred embodiment, pod 100 is sufficiently small so that it iscapable of creating an impression of a natural phenomenon such as afirefly or bioluminescence. For example, pod 100 may have acircumference of about 2.5 inches. Regardless, other shapes and sizesare within the scope of the current invention.

As illustrated, pod 100 may include upper dome 102 and lower dome 104which may join together to form housing 106 to contain variouscomponents of pod 100. Some components may be sealed from the water,while others may engage the water.

Pod 100 preferably houses light 110 which may provide the lightingeffect for system 1. Light 110 may be any of various types of lights. Ina preferred embodiment, light 110 comprises a light emitting diode(LED). In another form, light 110 may comprise an RGBW LED. Light 110may be housed within upper dome 102, so that it and its associatedelectronics 150 may be sealed from the water. Regardless of the shape ofpod 100, it is preferred that pod 100 have a low center of gravity sothat light 110 remains upward. Upper dome 102 may be clear or some otherconfiguration.

Pod 100 preferably includes multi-directional propulsion system 120. Asillustrated in FIGS. 5 and 10, for example, propulsion system 120 mayadvantageously allow pod 100 to be multi-directionally movable in an XYcoordinate system. Pod 100 may also include other propulsion means tolower or raise pod 100 while underwater. As such, additional visualeffects where light display device 10 submerges or nears the surface maybe provided.

Propulsion system 120 may include one or more directional thrustmotor(s) 121 coupled to propeller(s) 122 via propeller shaft(s) 124. Asillustrated, for example, in FIG. 4, directional thrust motor 121 may behoused within the interior of pod 100, while propeller 122 may bepositioned adjacent an exterior wall 126 of pod 100. Propeller shaft 124may pass through a throughbore 128 in wall 126.

External wall 126 may include one or more propeller seats or recesses130 that is sized and configured to receive a portion of propeller 122and allow propeller 122 to rotate freely therein. Pod 100 may alsoinclude propeller grill 132 for enclosing propeller 122. Grill 132 maybe sized and configured to securely fit into or engage propeller seat130.

As shown in FIGS. 4 and 5, pod 100 may include a plurality ofdirectional thrust motors 121 and propellers 122 to allow pod 100 tomove in different directions. In a preferred embodiment, pod 100includes four such directional thrust motors 121 and propellers 122 ineach quadrant of pod 100. In this configuration, one or more propellersmay be commanded to provide varying levels of thrust to control thedirection of pod 100. One, two, three or some other number of propellers122 may be used.

Pod 100 may include one or more battery pack(s) 140. Battery pack 140may be rechargeable, including for example, by induction charging. Inone form, pod 100 may include 2 or more battery packs 140 connected inseries which may advantageously allow extended run times before the pod100 must be docked for recharging or otherwise recharged.

Pod 100 may also include electronic control system 150 such as a printedcircuit board (PCB). Electronic control system 150 may allow pod 100 toreceive data stream 40 from control hub 20, for example, over a WiFinetwork. For example, electronic control system 150 may allow pod 100 toreceive a unique position command via data stream 40, compare theposition to its current position as determined by a GPS tracking system50, and then cause pod 100 to move to its new position by engaging oneor more directional thrust motors 120 and propellers 122 as appropriate.

Electronic control system 150 may receive and/or implement othercommands via the data stream 40, including but not limited to, commandsconcerning timing and/or speed, light color, brightness, saturationand/or other properties.

As an alternative to the remote control described above, pod 100 may bepreprogrammed and not rely on remotely internally provided commands. Tothis end, control system 150 may include software to control pod 100. Inthis embodiment, control system 150 may include an EEPROM that allowsdifferent control programs to be loaded to pod 100 to provide differentdisplays.

It is preferred that electronics 150 be housed within upper dome 102 andsealed from the water. Alternatively, electronics 150 may be potted andexposed to the water. Batteries 140 may also be sealed or be waterresistant or waterproof.

Lower dome 126 may also include a cleaning assembly (not shown) that maydispense cleaner through grills 132 to the water. In this manner, aspods 100 move about the pool or reservoir, they may provide a cleaningfunction.

It should be noted that the current invention is not limited to thedesign of pod 100 or light display device 10. That is, other types ofpropulsion systems to move device 10 beyond those disclosed herein maybe used. Furthermore, devices 10 may be coupled to a track to guidetheir movement. For example, devices 10 may travel along tracks at ornear the bottom or sides of the pool or reservoir.

Light displays that may be provided by the current invention are nowfurther described with references to FIGS. 6A-D, 7A-I, 8A-B and 9A-C.The current invention is not limited to the types of displays showntherein since these are only examples. Instead, the current inventioncovers wireless control and/or preprogrammed internal control of themovement of devices 10 to provide various types of light displays thatmove about a display reservoir in unique patterns and/or sequences. Tothis end, it is preferred that system 1 controls devices or pods 100 toprovide a choreography to convey a desired expression and/or tocomplement the surroundings. As noted above, this may include movementof devices 10 at or near the water's surface, or underwater. Andmovement of devices 10 may occur in the X-Y plane, or additionally inthe Z-direction where devices 10 submerge and rise up.

FIGS. 6A-D show a sequence whereby a plurality of pods 10 are controlledto move in a line and move into a concentric circle pattern. FIGS. 7A-Iand 8A-B illustrate various geometric patterns that may be displayed bysystem 1. FIGS. 9A-C illustrate various alternative naturalistic ororganic patterns that may be displayed by system 1 to create theimpression of organic phenomena such as swarming fireflies orbioluminescent creatures. As noted above, the display system 1 of thecurrent invention allows for virtually unlimited designs and/ormovements of the pods 10 to provide unlimited display options. Thewireless or internal preprogrammed control of devices 10 coupled withthe multi-directional propulsion system 120 allow for displays andmovements that are not obtainable with conventional light displays.

System 1 may be installed in various types of locations. For example, asshown in several of the figures, system 1 may be installed in a pool ata private residence. Alternatively, system 1 may be installed atcommercial locations. Furthermore, system 1 may be added to existingwater and/or light displays to further enhance such displays. In thisscenario, pods 100 or devices 10 may be commanded to move, light andotherwise complement the expressions of the existing display. In anyevent, the pool, reservoir or other body of water or liquid may vary insize, shape and configuration.

It is preferred that system 1 is scalable so that more pods 100 ordevices 10 may be added or deleted. To this end, the overall visualeffect of system 1 may be modified as desired.

Although certain presently preferred embodiments of the invention havebeen described herein, it will be apparent to those skilled in the artto which the invention pertains that variations and modifications of thedescribed embodiments may be made without departing from the spirit andscope of the invention.

What is claimed is:
 1. A light display system for use in a body of wateror other liquid, comprising: at least one movable light device that islocated in the body of water or other liquid, and that includes a light,a propulsion system and a control system; and at least one commandimplemented by the control system that controls one or more propertiesof the at least one movable light device.
 2. The light display system ofclaim 1, further comprising: a control hub for sending the at least onecommand wirelessly to the at least one movable light device.
 3. Thelight display system of claim 1, wherein the at least one command is adirection command.
 4. The light display system of claim 1, wherein theat least one command is a location command.
 5. The light display systemof claim 1, wherein the at least one command is a speed command.
 6. Thelight display system of claim 1, wherein the at least one command is alight color command.
 7. The light display system of claim 1, wherein theat least one command is a light brightness command.
 8. The light displaysystem of claim 1, wherein the movable light device further comprises atleast one rechargeable battery pack.
 9. The light display system ofclaim 2, wherein the control hub further comprises a battery charger tocharge the at least one movable light device.
 10. The light displaysystem of claim 1, further comprising: a control panel for transmittingsignals to the control hub that form the basis for the at least onecommand.
 11. The light display system of claim 1, further comprising aGPS tracking system for providing current location data to the at leastone light device.
 12. The light display system of claim 1, furthercomprising a computer, tablet or mobile phone for a user to control thesystem.
 13. A light display device for use in a body of water or otherliquid, comprising: a light; a propulsion system that is configured tomove the light display device multi-directionally; and an electroniccontrol system that implements at least one command to control one ormore properties of the light display device.
 14. The light displaydevice of claim 13, further comprising at least one rechargeable batterypack.
 15. The light display device of claim 13, wherein the lightcomprises an LED.
 16. The light display device of claim 13, wherein thepropulsion system comprises at least one propulsion motor operablyconnected to a propeller.
 17. The light display device of claim 13,wherein the propulsion system comprises four propulsion motors, each ofwhich is operably connected to a propeller.
 18. The light display deviceof claim 13, wherein the electronic control system comprises a PCB. 19.The light display device of claim 13, further comprising a housing thatcontains the light, the propulsion system and the electronic controlsystem.
 20. The underwater light display device of claim 19, wherein thehousing is spherical. 21-23. (canceled)